CN117399693A - Steel plate slitting and cutting device - Google Patents

Abstract

The invention provides a steel plate slitting cutting device which comprises a slitting machine, a carding unit, a plate cutting machine, a material ejection wheel, an upper cutter and a lower cutter. When the steel plate slitting cutting device is used, the coiled material is split into a plurality of strips through the slitting machine, the conveying direction of the strips is guided through the carding unit, and the cutting precision of the strips is ensured in the stable conveying process of the strips. After the batten passes through one end of the cutting edge of the upper cutter, the batten can be pressed inside the guide chute through the material ejection wheel, the batten positioned at the upper cutter stops moving and is driven to move upwards to cut off the batten, the batten can be fixed inside the guide chute through the arrangement of the material ejection wheel, and the work of the earlier-stage slitting machine is not influenced, so that the cutting efficiency of the batten is effectively improved.

Description

Steel plate slitting and cutting device

Technical Field

The invention belongs to the technical field of metal plate processing, and particularly relates to a steel plate slitting and cutting device.

Background

The sheet metal strip may serve as a raw material for some metal products. The desired metal part can be formed after a later rolling or welding. In the production process of the metal half strip, the metal coiled material is cut according to the length by adopting a cutting device after being subjected to strip cutting and rolling through a steel plate strip cutting machine. But at present to improve the production efficiency of the strip. The transverse shearing device is arranged at the rear of the metal slitting machine, and can directly cut according to the required length after slitting is completed according to the size requirement of the lath. However, when transversely cutting at present, the cutting can be performed only after the conveying of the preface slitting machine is stopped, and the production efficiency of the metal strip is affected.

Disclosure of Invention

The embodiment of the invention provides a steel plate slitting and cutting device, which aims to solve the problem of lower production efficiency in the red metal half-strip cutting process in the prior art.

In order to achieve the above purpose, the invention adopts the following technical scheme: provided is a steel plate slitting and cutting device, comprising:

the slitting machine is used for longitudinally slitting the coiled material;

the carding unit is arranged at the rear of the slitting machine and used for carding the strips cut by the slitting machine;

the plate cutting machine is arranged at the rear of the carding unit, one side, close to the carding unit, of the plate cutting machine is rotatably provided with a guide roller, and the guide roller is provided with a guide groove for guiding the battens;

the ejection wheel is movably arranged below the guide roller along the vertical direction and is used for compacting the plate material in the guide groove;

an upper cutter which is arranged on the plate cutting machine and is positioned behind the material guiding roller;

the lower cutter is movably arranged on the plate cutting machine along the vertical direction and is used for cutting off the batten in cooperation with the upper cutter.

In one possible implementation, the feed end of the slitting machine is provided with a conveying roller set for conveying coiled materials, the discharge end of the slitting machine is provided with an output roller set for outputting battens, and the conveying roller set is in transmission connection with the output roller set.

In one possible implementation manner, a driving unit for driving the ejector wheel to move upwards is arranged on the board cutting machine, and the driving unit comprises:

the mounting frame is mounted on the plate cutting machine, a sliding groove arranged along the vertical direction is formed in the mounting frame, the sliding grooves are formed in the two ends of the mounting shaft of the material ejection wheel, and the sliding grooves are arranged in the sliding grooves in a sliding manner;

the first wedge-shaped block is arranged on the mounting frame in a sliding manner along the conveying direction of the battens;

one end of the connecting rod is hinged to the mounting shaft of the material ejection wheel, and the other end of the connecting rod is hinged to the first wedge block;

the pushing assembly is arranged between the mounting frame and the first wedge-shaped block and is used for driving the first wedge-shaped block to move along the axis direction perpendicular to the hinge shaft of the connecting rod.

In one possible implementation, the pushing assembly includes:

the second wedge block is arranged on the mounting frame in a sliding manner along the axis direction of the hinge shaft on the connecting rod, a first inclined plane is arranged at one end of the first wedge block, and a second inclined plane in sliding fit with the first inclined plane is arranged at one end of the second wedge block;

the pushing rod is arranged on the mounting frame in a sliding mode along the sliding direction of the first wedge-shaped block, a third inclined plane is arranged at the other end of the second wedge-shaped block, and a fourth inclined plane which is in sliding fit with the third inclined plane is arranged on the pushing rod;

the driving assembly is arranged between the pushing rod and the mounting frame and is used for driving the pushing rod to move on the mounting frame.

In one possible implementation, the driving assembly includes:

the gear is rotatably arranged on the mounting frame, and the pushing rod is provided with teeth which are meshed with the gear;

the transmission rod is arranged on the lower cutter and is meshed with the gear.

In one possible implementation manner, an elastic piece for driving the first wedge block to move towards a direction approaching to the second wedge block is further arranged between the mounting frame and the first wedge block.

In one possible implementation, the carding unit comprises:

the material distributing wheel is rotatably arranged on the strip dividing machine, and baffle plates are arranged on the periphery of the material distributing wheel at intervals along the axial direction of the material distributing wheel;

the material supporting wheel is rotationally arranged below the material distributing wheel and is positioned between the two material blocking plates;

the movable frame is arranged on the slitting machine in a sliding manner along the vertical direction, and the material supporting wheel is arranged on the movable frame in a rotating manner.

In one possible implementation manner, the slitter is further provided with a lifting assembly for driving the moving frame to move up and down, and the lifting assembly includes:

the guide rod is arranged on the mounting frame in a sliding manner along the sliding direction of the pushing rod, the guide rod and the pushing rod are arranged at two sides of the gear at intervals, and the guide rod and the gear are mutually meshed;

the first sliding groove is arranged on the movable frame;

the second sliding groove and the first sliding groove are arranged on the movable frame in a staggered manner along the vertical direction;

the transition chute is arranged between the first chute and the second chute and is used for communicating the first chute with the second chute;

the guide wheel is rotatably arranged at the end part of the guide rod, the first sliding groove, the second sliding groove and the transition sliding groove form a guide sliding way, and the guide wheel is arranged inside the guide sliding way in a rolling way.

In one possible implementation manner, an adjusting frame is movably arranged above the moving frame, the position of the adjusting frame on the moving frame has the freedom degree of adjustment along the vertical direction, and the material supporting wheel is arranged on the adjusting frame.

In one possible implementation, an adjusting assembly for adjusting the height of the adjusting frame is disposed between the moving frame and the adjusting frame, and the adjusting assembly includes:

the number of the adjusting shafts is two, and the two adjusting shafts are arranged in parallel at intervals along the horizontal direction;

one end of the first supporting rod is hinged to the adjusting shaft, and the other end of the first supporting rod is hinged to the adjusting frame;

one end of the second supporting rod is hinged to the adjusting shaft, and the other end of the second supporting rod is hinged to the moving frame;

the adjusting rod is arranged between the two adjusting shafts and used for adjusting the distance between the two adjusting shafts.

Compared with the prior art, the scheme that this application embodiment shows, through being provided with the slitting machine, the slitting machine can cut apart into a plurality of laths with the coiled material along its width direction, and after the lath after cutting apart was accomplished was through carding unit, the lath can be neat carry to the trigger direction. The front sections of the upper cutter and the lower cutter of the plate cutting machine are provided with a guide roller and a liftout wheel, the guide roller is provided with a guide groove with the width equivalent to that of the strip, and the strip is tightly pressed in the guide groove through the liftout roller. When the strip cutting device is used, the coiled material is divided into a plurality of strips through the strip dividing machine, the conveying direction of the strips is guided by the carding unit, and the cutting precision of the strips is guaranteed in the stable conveying process of the strips. After the batten passes through one end of the cutting edge of the upper cutter, the batten can be pressed inside the guide chute through the material ejection wheel, the batten positioned at the upper cutter stops moving and is driven to move upwards to cut off the batten, the batten can be fixed inside the guide chute through the arrangement of the material ejection wheel, and the work of the earlier-stage slitting machine is not influenced, so that the cutting efficiency of the batten is effectively improved.

Drawings

Fig. 1 is a schematic structural view of a steel plate slitting and cutting device according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a carding unit and a driving unit according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a mounting frame according to an embodiment of the present invention;

fig. 4 is a schematic view of an installation structure of an adjusting frame according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a board cutting machine according to an embodiment of the present invention.

Reference numerals illustrate:

1. a slitting machine; 2. a carding unit; 21. a material distributing wheel; 211. a striker plate; 22. a material supporting wheel; 23. a moving rack; 231. a first chute; 232. a second chute; 233. a transition chute; 24. a guide rod; 241. a guide wheel; 25. an adjusting frame; 26. an adjustment assembly; 261. an adjusting shaft; 262. a first support bar; 263. a second support bar; 264. an adjusting rod; 3. plate cutting machine; 31. an upper cutter; 32. a lower cutter; 33. a guide roller; 34. a material ejection wheel; 4. a conveying roller set; 5. an output roller group; 6. a driving unit; 61. a mounting frame; 62. a first wedge block; 63. a connecting rod; 64. a second wedge block; 65. a push rod; 66. a gear; 67. a transmission rod; 68. an elastic member;

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Referring to fig. 1 and 2 together, the steel plate slitting and cutting device provided by the invention will now be described. The steel plate slitting cutting device comprises a slitting machine 1, a carding unit 2, a plate cutting machine 3, a jacking wheel 34, an upper cutter 31 and a lower cutter 32. The slitting machine 1 is used for longitudinally slitting coiled materials; the carding unit 2 is arranged at the rear of the slitting machine 1 and is used for carding the strips cut by the slitting machine 1; the plate cutting machine 3 is arranged at the rear of the carding unit 2, one side of the plate cutting machine 3, which is close to the carding unit 2, is rotatably provided with a guide roller 33, and a guide groove for guiding the battens is arranged on the guide roller 33; the material ejection wheel 34 is movably arranged below the material guide roller 33 along the vertical direction and is used for compacting the plate material in the material guide groove; the upper cutter 31 is arranged on the plate cutting machine 3 and is positioned behind the material guiding roller 33; the lower cutter 32 is movably provided on the panel cutter 3 in a vertical direction for cutting the panel in cooperation with the upper cutter 31.

Compared with the prior art, the steel plate slitting cutting device provided by the embodiment has the advantages that the slitting machine 1 is arranged, the slitting machine 1 can divide coiled materials into a plurality of strips along the width direction of the coiled materials, and after the strips after division pass through the carding unit 2, the strips can be orderly conveyed towards the plate cutting machine 3. The front sections of the upper cutter 31 and the lower cutter 32 of the plate cutting machine 3 are provided with a guide roller 33 and a jacking wheel 34, a guide groove with the width equivalent to that of the strip is arranged on the guide roller 33, and the strip is pressed inside the guide groove by the jacking roller. When the strip cutting machine is used, the coiled material is divided into a plurality of strips through the strip cutting machine 1, the conveying direction of the strips is guided through the carding unit 2, and the cutting precision of the strips is guaranteed in the stable conveying process of the strips. After the batten passes through one end of the cutting edge of the upper cutter 31, the batten can be pressed inside the guide chute through the material ejection wheel 34, the batten positioned at the upper cutter 31 stops moving and drives the lower cutter 32 to move upwards to cut off the batten, and the batten can be fixed inside the guide chute through the arrangement of the material ejection wheel 34 without influencing the work of the earlier-stage slitting machine 1, so that the cutting efficiency of the batten is effectively improved.

Specifically, in the present embodiment, the upper cutter 31 is fixedly mounted above the board cutting machine 3 by bolts, and the guide roller 33 is rotatably provided above the board cutting machine 3, and a plurality of guide grooves are arranged on the guide roller 33 at intervals along the length direction thereof, so that a plurality of strips can be accommodated and conveyed at the same time.

Specifically, in this embodiment, a power assembly for driving the lower cutter 32 to slide on the board cutting machine 3 is further provided on the board cutting machine 3, and the power assembly includes:

the power shaft, length direction along the length direction setting of cutter 32 down, the articulated first guide arm and the second guide arm that are provided with on the power shaft, first guide arm and second guide arm coaxial setting on the power shaft, and the other end of first guide arm articulates the setting on cutter 32 down, and the other end of second guide arm articulates the setting on trigger 3. One end of the power shaft is provided with a hydraulic cylinder, a fixing part of the hydraulic cylinder is hinged on the plate cutting machine 3, and a driving end of the hydraulic cylinder is hinged on the power shaft. When the driving shaft of the hydraulic cylinder moves, the power shaft can be driven to move, so that the first guide rod and the second guide rod swing, and the lower cutter 32 is driven to move.

In some embodiments, the slitter 1 may be configured as shown in fig. 2. Referring to fig. 2, a feeding end of the slitting machine 1 is provided with a conveying roller set 4 for conveying coiled materials, a discharging end of the slitting machine 1 is provided with an output roller set 5 for outputting battens, and the conveying roller set 4 is in transmission connection with the output roller set 5. The conveying roller set 4 and the output roller set 5 both comprise a power roller and a pressing roller for pressing the coiled material or the strip on the power roller, and the pressing roller moves towards the direction close to the power roller through a hydraulic cylinder and presses the coiled material or the strip on the power roller. The outer diameters of the conveying roller set 4 and the power rollers on the conveying roller set 4 are the same, and the conveying roller set 4 and the output roller set 5 are connected through a chain or a size transmission, so that the conveying speeds of the conveying roller set 4 and the output roller set 5 are the same. The function of the conveyor roller set 4 is to convey the web into the slitter 1 for slitting. The output roller set 5 is used for preventing the batten from moving towards the inside of the slitting machine 1 and generating acting force towards the rear after the jacking wheels 34 press the batten inside the guide chute, so that the normal operation of the slitting machine 1 is affected.

In some embodiments, the slitter 1 may be configured as shown in fig. 2. Referring to fig. 2, the board cutting machine 3 is provided with a driving unit 6 for driving the ejector wheel 34 to move upward, and the driving unit 6 includes a mounting frame 61, a first wedge block 62, a connecting rod 63, and a pushing assembly. The mounting frame 61 is mounted on the plate cutting machine 3, the mounting frame 61 is provided with a chute arranged along the vertical direction, both ends of the mounting shaft of the material ejection wheel 34 are provided with the chute, and the material ejection wheel is arranged in the chute in a sliding manner; the first wedge block 62 is slidably provided on the mounting frame 61 in the conveying direction of the slat; one end of the connecting rod 63 is hinged on the mounting shaft of the ejector wheel 34, and the other end is hinged on the first wedge-shaped block 62; the pushing assembly is disposed between the mounting frame 61 and the first wedge block 62, and is used for driving the first wedge block 62 to move along the axis direction perpendicular to the hinge shaft of the connecting rod 63. The mounting frame 61 is fixedly mounted on the board cutting machine 3, and two wing plates are mounted on the mounting frame 61 at intervals along the axial direction of the ejector wheel 34, and the sliding groove is positioned on the wing plates. A plurality of ejector wheels 34 are mounted on the mounting shaft of the ejector wheel 34, and the ejector wheels 34 are fixedly mounted on the mounting shaft or rotatably arranged on the mounting shaft. The ejector wheel 34 can be driven to move in the guide chute by sliding the mounting shaft in the chute. The mounting shaft is hinged with a connecting rod 63. And the first wedge block 62 is slidably arranged below the connecting rod 63 along the slat conveying direction, and the connecting rod 63 can be driven to swing and the mounting shaft can be driven to move up and down through the sliding of the first wedge block 62.

Preferably, in this embodiment, the connecting rods 63 and the first wedge blocks 62 are provided at both ends of the installation shaft, so that the stability of the installation shaft sliding in the vertical direction is improved.

In some embodiments, the pushing assembly may take the configuration shown in fig. 2. Referring to fig. 2, the push assembly includes a second wedge block 64, a push rod 65, and a take-up assembly. The second wedge block 64 is slidably arranged on the mounting frame 61 along the axis direction of the hinge shaft on the connecting rod 63, one end of the first wedge block 62 is provided with a first inclined plane, and one end of the second wedge block 64 is provided with a second inclined plane which is slidably matched with the first inclined plane; the pushing rod 65 is slidably arranged on the mounting frame 61 along the sliding direction of the first wedge-shaped block 62, a third inclined plane is arranged at the other end of the second wedge-shaped block 64, and a fourth inclined plane which is slidably matched with the third inclined plane is arranged on the pushing rod 65; the driving component is disposed between the pushing rod 65 and the mounting frame 61, and is used for driving the pushing rod 65 to move on the mounting frame 61. When the second wedge block 64 moves towards the direction approaching the first wedge block 62, the first wedge block 62 slides towards the direction far away from the first wedge block 62 through the matched sliding guide between the first inclined surface and the second inclined surface, and the connecting rod 63 is driven to swing, so that the mounting shaft of the ejector wheel 34 slides along the vertical direction. The sliding direction of the push rod 65 is set along the conveying direction of the slats. The push rod 65 can drive the second wedge block 64 to slide along the length direction thereof by guiding the third inclined surface and the fourth inclined surface when moving in the slat conveying direction.

Specifically, in this embodiment, the first inclined plane and the second inclined plane are parallel to each other and are disposed in a fitting manner.

Specifically, in the present embodiment, the length of the connecting rod 63 is adjustably set so that the moving stroke of the ejector wheel 34 can be adjusted.

Preferably, in this embodiment, the mounting frame 61 is provided with sliding grooves for placing the first wedge block 62 and the second wedge block 64.

In some embodiments, the driving assembly may have a structure as shown in fig. 2. Referring to fig. 2, the drive assembly includes a gear 66 and a drive rod 67. The gear 66 is rotatably arranged on the mounting frame 61, and the push rod 65 is provided with teeth which are meshed with the gear 66; the transmission rod 67 is mounted on the lower cutter 32, and the transmission rod 67 and the gear 66 are engaged with each other. The gear 66 is rotatably provided on the mounting frame 61, and a transmission rod 67 is provided on one side of the gear 66 in engagement. The transmission rod 67 is disposed in a vertical direction and is mounted on a mount of the lower cutter 32. When the lower cutter 32 moves up and down, the transmission rod 67 is synchronously driven to move up and down. Meanwhile, the push rod 65 is located at the top of the gear 66, and during operation, the lower cutter 32 moves upward and drives the transmission rod 67 to move together. The transmission rod 67 drives the gear 66 to rotate, and when the gear 66 rotates, the push rod 65 above can be driven to move together, and the first wedge block 62 and the second wedge block 64 are combined to control the ejector wheel 34 to move up and down.

Preferably, in this embodiment, the first wedge 62 and the second wedge 64 are provided. When the sliding travel of the first inclined plane and the second inclined plane or the third inclined plane and the fourth inclined plane is too large to separate from each other, the lower cutter 32 can still move continuously. The lower cutter 32 cannot move when the moving stroke of the ejector wheel 34 is locked.

Specifically, in the present embodiment, by the arrangement of the driving unit 6, it is possible to move the ejector wheel 34 upward at the same time as the lower cutter 32 moves upward, the slat is pressed inside the guide chute before the lower cutter 32 contacts the upper cutter 31, and the lower cutter 32 continues to move to cut the slat.

In some embodiments, the mounting frame 61 may be configured as shown in fig. 2. Referring to fig. 2, an elastic member 68 for driving the first wedge block 62 to move in a direction approaching the second wedge block 64 is further provided between the mounting frame 61 and the first wedge block 62. The elastic member 68 is a spring, or a cylinder is employed. When the lower cutter 32 is returned, the second wedge 64 is driven to move in a direction approaching the first wedge 62 by the provision of the elastic member 68. And simultaneously, the connecting rod 63 on the second wedge-shaped block 64 drives the mounting shaft of the ejector wheel 34 to move downwards. So as to drive the ejector wheel 34 to move away from the guide roller 33.

In some embodiments, the carding unit 2 may take the configuration shown in fig. 2. Referring to fig. 2, the carding unit 2 includes a feed wheel 21, a carrier wheel 22, and a moving frame 23. The material dividing wheel 21 is rotatably arranged on the slitting machine 1, and baffle plates 211 are arranged on the periphery of the material dividing wheel 21 at intervals along the axial direction of the material dividing wheel 21; the material supporting wheel 22 is rotatably arranged below the material distributing wheel 21 and is positioned between the two material blocking plates 211; the moving frame 23 is slidably disposed on the slitting machine 1 in the vertical direction, and the material supporting wheel 22 is rotatably disposed on the moving frame 23. The separating wheel 21 is rotatably arranged above the slitting machine 1 and the slats pass between two blanking plates 211 at the underside of the separating wheel 21. The supporting wheel 22 is located below the distributing wheel 21 and is used for supporting the batten between the two baffle plates 211, so that stable conveying of the batten is ensured. The movable frame 23 can drive the material supporting wheel 22 to move up and down. When the batten is propped up inside the guide chute by the liftout wheel 34, the movable frame 23 can drive the material supporting wheel 22 to move downwards, so that the material storage space at the carding unit 2 can be increased. The strip which is to be continuously fed up into the carding unit 2 is temporarily held between the dragging wheel and the separating wheel 21. And after the cutting of the board cutting machine 3 is completed, the pushing wheel 34 loosens the batten, the moving frame 23 moves upwards, and the batten can be pushed to move forward rapidly, so that the temporary storage effect of the batten can be realized in the cutting process. The operation of the earlier stage slitter 1 is not affected.

In some embodiments, the lifting assembly may be configured as shown in fig. 2. Referring to fig. 2, the slitter 1 is further provided with a lifting assembly for driving the moving frame 23 to move up and down, and the lifting assembly includes a guide bar 24, a first chute 231, a second chute 232, a transition chute 233, and a guide wheel 241. The guide rod 24 is arranged on the mounting frame 61 in a sliding manner along the sliding direction of the pushing rod 65, the guide rod 24 and the pushing rod 65 are arranged at two sides of the gear 66 at intervals, and the guide rod 24 and the gear 66 are meshed with each other; the first chute 231 is mounted on the moving frame 23; the second sliding groove 232 and the first sliding groove 231 are arranged on the movable frame 23 in a staggered manner along the vertical direction; the transition chute 233 is disposed between the first chute 231 and the second chute 232, and is used for communicating the first chute 231 and the second chute 232; the guide wheel 241 is rotatably disposed at the end of the guide rod 24, the first chute 231, the second chute 232 and the transition chute 233 form a guide chute, and the guide wheel 241 is rollingly disposed inside the guide chute. The guide bar 24 is positioned below the gear 66 and is disposed in meshing engagement with the gear 66. And the length direction and the sliding direction of the guide bar 24 are both set along the conveying direction of the slat. When the gear 66 rotates, the guide rod 24 can be driven to slide, and the length direction of the first sliding groove 231 and the second sliding groove 232 is the same as the length direction of the guide rod 24, and the guide wheel 241 can be switched between the first sliding groove 231 and the second sliding groove 232 through the transition sliding groove 233. The first chute 231 and the second chute 232 are formed with a height difference, so that the moving frame 23 can be driven to move up and down. Therefore, the movable frame 23 and the ejector wheel 34 can be synchronously driven to move together in the moving process of the lower cutter 32.

Preferably, in the present embodiment, the inner wall of the transition chute 233 has an arc-shaped structure, so that the guide wheel 241 is convenient to move inside the arc-shaped chute.

In some embodiments, the movable frame 23 may have a structure as shown in fig. 2. Referring to fig. 2, an adjusting frame 25 is also movably provided above the moving frame 23, the position of the adjusting frame 25 on the moving frame 23 has a degree of freedom to be adjusted in the vertical direction, and the supporting wheel 22 is mounted on the adjusting frame 25. The adjusting frame 25 is used for adjusting the height position of the material supporting wheel 22 in the moving travel range of the moving frame 23. Alternatively, when the first chute 231 is greater in height than the second chute 232, and when the guide wheel 241 is positioned inside the first chute 231, the slats are conveyed in a horizontal direction while being overlapped on the pallet wheel 22, thereby maintaining stability during conveying of the slats.

In some embodiments, the adjusting bracket 25 may have a structure as shown in fig. 2. Referring to fig. 2, an adjusting assembly 26 for adjusting the height of the adjusting frame 25 is provided between the moving frame 23 and the adjusting frame 25, and the adjusting assembly 26 includes an adjusting shaft 261, a first supporting bar 262, a second supporting bar 263, and an adjusting bar 264. The number of the adjusting shafts 261 is two, and the two adjusting shafts 261 are arranged in parallel at intervals along the horizontal direction; one end of the first supporting rod 262 is hinged on the adjusting shaft 261, and the other end is hinged on the adjusting frame 25; one end of the second support rod 263 is hinged on the adjusting shaft 261, and the other end is hinged on the movable frame 23; an adjusting lever 264 is provided between the two adjusting shafts 261 for adjusting the interval between the two adjusting shafts 261. The first support bar 262 and the second support bar 263 are provided on both the two adjustment shafts 261. And the two first support rods 262 on the two adjustment shafts 261 and the two second support rods 263 on the two adjustment shafts 261 are inclined toward each other in a direction away from the adjustment shafts 261. The length direction of the adjusting lever 264 is set along the arrangement direction of the two adjusting shafts 261, the adjusting lever 264 is threaded with the two adjusting shafts 261 by screws, and the rotation directions of the threads are opposite. When the adjustment lever 264 is rotated, the two adjustment shafts 261 can be adjusted to move in directions approaching or separating from each other, thereby adjusting the distance between the adjustment frame 25 and the moving frame 23.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (10)

1. A steel sheet slitting cutting device, characterized by comprising:

the slitting machine (1) is used for longitudinally slitting the coiled material;

the carding unit (2) is arranged behind the slitting machine (1) and is used for carding the strips cut by the slitting machine (1);

the plate cutting machine (3) is arranged at the rear of the carding unit (2), a material guide roller (33) is rotatably arranged on one side, close to the carding unit (2), of the plate cutting machine (3), and a material guide groove for guiding the batten is arranged on the material guide roller (33);

the ejection wheel (34) is movably arranged below the guide roller (33) along the vertical direction and is used for compacting the plate material in the guide groove;

an upper cutter (31) which is arranged on the plate cutting machine (3) and is positioned behind the material guiding roller (33);

the lower cutter (32) is movably arranged on the plate cutting machine (3) along the vertical direction and is used for cutting off the batten in cooperation with the upper cutter (31).

2. The steel plate slitting cutting device according to claim 1, wherein a feeding end of the slitting machine (1) is provided with a conveying roller set (4) for conveying coiled materials, a discharging end of the slitting machine (1) is provided with an output roller set (5) for outputting battens, and the conveying roller set (4) is in transmission connection with the output roller set (5).

3. The slitting cutting apparatus of claim 1, wherein the guillotine machine (3) is provided with a driving unit (6) for driving the ejector wheel (34) to move upward, the driving unit (6) comprising:

the mounting frame (61) is mounted on the plate cutting machine (3), a chute which is arranged along the vertical direction is arranged on the mounting frame (61), and both ends of a mounting shaft of the material ejection wheel (34) are respectively provided with the chute and are arranged in the chute in a sliding manner;

a first wedge (62) slidably disposed on the mounting frame (61) in the conveying direction of the slat;

one end of the connecting rod (63) is hinged to the mounting shaft of the material ejection wheel (34), and the other end of the connecting rod is hinged to the first wedge block (62);

the pushing assembly is arranged between the mounting frame (61) and the first wedge-shaped block (62) and is used for driving the first wedge-shaped block (62) to move along the axis direction perpendicular to the hinge shaft of the connecting rod (63).

4. A steel sheet slitting severing device as claimed in claim 3 wherein the pushing assembly comprises:

the second wedge-shaped block (64) is arranged on the mounting frame (61) in a sliding manner along the axis direction of the hinge shaft on the connecting rod (63), a first inclined plane is arranged at one end of the first wedge-shaped block (62), and a second inclined plane which is in sliding fit with the first inclined plane is arranged at one end of the second wedge-shaped block (64);

the pushing rod (65) is arranged on the mounting frame (61) in a sliding mode along the sliding direction of the first wedge-shaped block (62), a third inclined plane is arranged at the other end of the second wedge-shaped block (64), and a fourth inclined plane which is in sliding fit with the third inclined plane is arranged on the pushing rod (65);

the driving assembly is arranged between the pushing rod (65) and the mounting frame (61) and is used for driving the pushing rod (65) to move on the mounting frame (61).

5. The steel plate slitting cutter of claim 4, wherein the driving assembly comprises:

the gear (66) is rotatably arranged on the mounting frame (61), and teeth which are meshed with the gear (66) are arranged on the pushing rod (65);

and the transmission rod (67) is arranged on the lower cutter (32), and the transmission rod (67) and the gear (66) are meshed with each other.

6. The steel plate slitting cutting device according to claim 4, wherein an elastic member (68) for driving the first wedge block (62) to move in a direction approaching the second wedge block (64) is further provided between the mounting frame (61) and the first wedge block (62).

7. The slitting cutting apparatus of steel sheet according to claim 5, wherein the carding unit (2) comprises:

the material dividing wheel (21) is rotatably arranged on the strip dividing machine (1), and baffle plates (211) are arranged on the periphery of the material dividing wheel (21) at intervals along the axial direction of the material dividing wheel (21);

the material supporting wheel (22) is rotatably arranged below the material distributing wheel (21) and is positioned between the two material blocking plates (211);

the movable frame (23) is arranged on the slitting machine (1) in a sliding manner along the vertical direction, and the material supporting wheel (22) is rotatably arranged on the movable frame (23).

8. The steel plate slitting cutting apparatus according to claim 7, wherein the slitting machine (1) is further provided with a lifting assembly for driving the moving frame (23) to move up and down, the lifting assembly comprising:

the guide rods (24) are arranged on the mounting frame (61) in a sliding mode along the sliding direction of the pushing rods (65), the guide rods (24) and the pushing rods (65) are arranged on two sides of the gear (66) at intervals, and the guide rods (24) and the gear (66) are meshed with each other;

a first chute (231) mounted on the moving frame (23);

the second sliding groove (232) and the first sliding groove (231) are arranged on the movable frame (23) in a staggered manner along the vertical direction;

the transition chute (233) is arranged between the first chute (231) and the second chute (232) and is used for communicating the first chute (231) with the second chute (232);

the guide wheel (241) is rotatably arranged at the end part of the guide rod (24), the first sliding groove (231), the second sliding groove (232) and the transition sliding groove (233) form a guide sliding way, and the guide wheel (241) is arranged inside the guide sliding way in a rolling way.

9. The steel plate slitting cutting device according to claim 7, characterized in that an adjusting frame (25) is movably arranged above the moving frame (23), the position of the adjusting frame (25) on the moving frame (23) has a degree of freedom of adjustment along the vertical direction, and the material supporting wheel (22) is mounted on the adjusting frame (25).

10. The steel plate slitting cutting device according to claim 9, wherein an adjusting assembly (26) for adjusting the height of the adjusting frame (25) is provided between the moving frame (23) and the adjusting frame (25), the adjusting assembly (26) comprising:

the number of the adjusting shafts (261) is two, and the two adjusting shafts (261) are arranged in parallel at intervals along the horizontal direction;

a first support rod (262), one end of which is hinged on the adjusting shaft (261) and the other end of which is hinged on the adjusting frame (25);

a second support rod (263) with one end hinged to the adjusting shaft (261) and the other end hinged to the movable frame (23);

and an adjusting rod (264) arranged between the two adjusting shafts (261) and used for adjusting the distance between the two adjusting shafts (261).